%
% (c) The GRASP/AQUA Project, Glasgow University, 1992-1998
%
-\section[Unify]{Unifier}
-
-The unifier is now squarely in the typechecker monad (because of the
-updatable substitution).
+\section{Type subsumption and unification}
\begin{code}
-module TcUnify ( unifyTauTy, unifyTauTyList, unifyTauTyLists,
- unifyFunTy, unifyListTy, unifyTupleTy, unifyUnboxedTupleTy,
- unifyKind, unifyKinds, unifyTypeKind
- ) where
+module TcUnify (
+ -- Full-blown subsumption
+ tcSubOff, tcSubExp, tcGen,
+ checkSigTyVars, checkSigTyVarsWrt, sigCtxt, findGlobals,
+
+ -- Various unifications
+ unifyTauTy, unifyTauTyList, unifyTauTyLists,
+ unifyKind, unifyKinds, unifyFunKind,
+ checkExpectedKind,
+
+ --------------------------------
+ -- Holes
+ Expected(..), newHole, readExpectedType,
+ zapExpectedType, zapExpectedTo, zapExpectedBranches,
+ subFunTys, unifyFunTy,
+ zapToListTy, unifyListTy,
+ zapToPArrTy, unifyPArrTy,
+ zapToTupleTy, unifyTupleTy
+
+ ) where
#include "HsVersions.h"
--- friends:
-import TcMonad
-import Type ( Type(..), tyVarsOfType, funTyCon,
- mkFunTy, splitFunTy_maybe, splitTyConApp_maybe,
- Kind, boxedTypeKind, typeCon, anyBoxCon, anyBoxKind,
- splitAppTy_maybe,
- tidyOpenType, tidyOpenTypes, tidyTyVar
- )
-import TyCon ( TyCon, isTupleTyCon, isUnboxedTupleTyCon,
- tyConArity )
-import Name ( isSystemName )
-import Var ( TyVar, tyVarKind, varName )
-import VarEnv
-import VarSet ( varSetElems )
-import TcType ( TcType, TcTauType, TcTyVar, TcKind,
- newTyVarTy, newOpenTypeKind, newTyVarTy_OpenKind,
- tcGetTyVar, tcPutTyVar, zonkTcType, tcTypeKind
- )
--- others:
-import BasicTypes ( Arity )
-import TysWiredIn ( listTyCon, mkListTy, mkTupleTy, mkUnboxedTupleTy )
-import PprType () -- Instances
-import Util
+
+import HsSyn ( HsExpr(..) )
+import TcHsSyn ( mkHsLet, mkHsDictLam,
+ ExprCoFn, idCoercion, isIdCoercion, mkCoercion, (<.>), (<$>) )
+import TypeRep ( Type(..), PredType(..), TyNote(..) )
+
+import TcRnMonad -- TcType, amongst others
+import TcType ( TcKind, TcType, TcSigmaType, TcRhoType, TcTyVar, TcTauType,
+ TcTyVarSet, TcThetaType, TyVarDetails(SigTv),
+ isTauTy, isSigmaTy, mkFunTys, mkTyConApp,
+ tcSplitAppTy_maybe, tcSplitTyConApp_maybe,
+ tcGetTyVar_maybe, tcGetTyVar,
+ mkFunTy, tyVarsOfType, mkPhiTy,
+ typeKind, tcSplitFunTy_maybe, mkForAllTys,
+ isSkolemTyVar, isUserTyVar,
+ tidyOpenType, tidyOpenTypes, tidyOpenTyVar, tidyOpenTyVars,
+ allDistinctTyVars, pprType )
+import Kind ( Kind(..), SimpleKind, KindVar, isArgTypeKind,
+ openTypeKind, liftedTypeKind, mkArrowKind,
+ isOpenTypeKind, argTypeKind, isLiftedTypeKind, isUnliftedTypeKind,
+ isSubKind, pprKind, splitKindFunTys )
+import Inst ( newDicts, instToId, tcInstCall )
+import TcMType ( getTcTyVar, putTcTyVar, tcInstType, newKindVar,
+ newTyVarTy, newTyVarTys, zonkTcKind,
+ zonkTcType, zonkTcTyVars, zonkTcTyVarsAndFV,
+ readKindVar,writeKindVar )
+import TcSimplify ( tcSimplifyCheck )
+import TysWiredIn ( listTyCon, parrTyCon, tupleTyCon )
+import TcEnv ( tcGetGlobalTyVars, findGlobals )
+import TyCon ( TyCon, tyConArity, isTupleTyCon, tupleTyConBoxity )
+import Id ( Id, mkSysLocal )
+import Var ( Var, varName, tyVarKind )
+import VarSet ( emptyVarSet, unitVarSet, unionVarSet, elemVarSet, varSetElems )
+import VarEnv
+import Name ( isSystemName )
+import ErrUtils ( Message )
+import SrcLoc ( noLoc )
+import BasicTypes ( Boxity, Arity, isBoxed )
+import Util ( equalLength, lengthExceeds, notNull )
import Outputable
\end{code}
+Notes on holes
+~~~~~~~~~~~~~~
+* A hole is always filled in with an ordinary type, not another hole.
%************************************************************************
%* *
-\subsection{The Kind variants}
+\subsection{'hole' type variables}
%* *
%************************************************************************
\begin{code}
-unifyKind :: TcKind -- Expected
- -> TcKind -- Actual
- -> TcM s ()
-unifyKind k1 k2
- = tcAddErrCtxtM (unifyCtxt "kind" k1 k2) $
- uTys k1 k1 k2 k2
-
-unifyKinds :: [TcKind] -> [TcKind] -> TcM s ()
-unifyKinds [] [] = returnTc ()
-unifyKinds (k1:ks1) (k2:ks2) = unifyKind k1 k2 `thenTc_`
- unifyKinds ks1 ks2
-unifyKinds _ _ = panic "unifyKinds: length mis-match"
+data Expected ty = Infer (TcRef ty) -- The hole to fill in for type inference
+ | Check ty -- The type to check during type checking
+
+newHole :: TcM (TcRef ty)
+newHole = newMutVar (error "Empty hole in typechecker")
+
+readExpectedType :: Expected ty -> TcM ty
+readExpectedType (Infer hole) = readMutVar hole
+readExpectedType (Check ty) = returnM ty
+
+zapExpectedType :: Expected TcType -> Kind -> TcM TcTauType
+-- In the inference case, ensure we have a monotype
+-- (including an unboxed tuple)
+zapExpectedType (Infer hole) kind
+ = do { ty <- newTyVarTy kind ;
+ writeMutVar hole ty ;
+ return ty }
+
+zapExpectedType (Check ty) kind
+ | typeKind ty `isSubKind` kind = return ty
+ | otherwise = do { ty1 <- newTyVarTy kind
+ ; unifyTauTy ty1 ty
+ ; return ty }
+ -- The unify is to ensure that 'ty' has the desired kind
+ -- For example, in (case e of r -> b) we push an OpenTypeKind
+ -- type variable
+
+zapExpectedTo :: Expected TcType -> TcTauType -> TcM ()
+zapExpectedTo (Infer hole) ty2 = writeMutVar hole ty2
+zapExpectedTo (Check ty1) ty2 = unifyTauTy ty1 ty2
+
+zapExpectedBranches :: [a] -> Expected TcType -> TcM (Expected TcType)
+-- Zap the expected type to a monotype if there is more than one branch
+zapExpectedBranches branches exp_ty
+ | lengthExceeds branches 1 = zapExpectedType exp_ty openTypeKind `thenM` \ exp_ty' ->
+ return (Check exp_ty')
+ | otherwise = returnM exp_ty
+
+instance Outputable ty => Outputable (Expected ty) where
+ ppr (Check ty) = ptext SLIT("Expected type") <+> ppr ty
+ ppr (Infer hole) = ptext SLIT("Inferring type")
+\end{code}
+
+
+%************************************************************************
+%* *
+\subsection[Unify-fun]{@unifyFunTy@}
+%* *
+%************************************************************************
+
+@subFunTy@ and @unifyFunTy@ is used to avoid the fruitless
+creation of type variables.
+
+* subFunTy is used when we might be faced with a "hole" type variable,
+ in which case we should create two new holes.
+
+* unifyFunTy is used when we expect to encounter only "ordinary"
+ type variables, so we should create new ordinary type variables
+
+\begin{code}
+subFunTys :: [pat]
+ -> Expected TcRhoType -- Fail if ty isn't a function type
+ -> ([(pat, Expected TcRhoType)] -> Expected TcRhoType -> TcM a)
+ -> TcM a
+
+subFunTys pats (Infer hole) thing_inside
+ = -- This is the interesting case
+ mapM new_pat_hole pats `thenM` \ pats_w_holes ->
+ newHole `thenM` \ res_hole ->
+
+ -- Do the business
+ thing_inside pats_w_holes (Infer res_hole) `thenM` \ answer ->
+
+ -- Extract the answers
+ mapM read_pat_hole pats_w_holes `thenM` \ arg_tys ->
+ readMutVar res_hole `thenM` \ res_ty ->
+
+ -- Write the answer into the incoming hole
+ writeMutVar hole (mkFunTys arg_tys res_ty) `thenM_`
+
+ -- And return the answer
+ returnM answer
+ where
+ new_pat_hole pat = newHole `thenM` \ hole -> return (pat, Infer hole)
+ read_pat_hole (pat, Infer hole) = readMutVar hole
+
+subFunTys pats (Check ty) thing_inside
+ = go pats ty `thenM` \ (pats_w_tys, res_ty) ->
+ thing_inside pats_w_tys res_ty
+ where
+ go [] ty = return ([], Check ty)
+ go (pat:pats) ty = unifyFunTy ty `thenM` \ (arg,res) ->
+ go pats res `thenM` \ (pats_w_tys, final_res) ->
+ return ((pat, Check arg) : pats_w_tys, final_res)
+
+unifyFunTy :: TcRhoType -- Fail if ty isn't a function type
+ -> TcM (TcType, TcType) -- otherwise return arg and result types
+
+unifyFunTy ty@(TyVarTy tyvar)
+ = getTcTyVar tyvar `thenM` \ maybe_ty ->
+ case maybe_ty of
+ Just ty' -> unifyFunTy ty'
+ Nothing -> unify_fun_ty_help ty
+
+unifyFunTy ty
+ = case tcSplitFunTy_maybe ty of
+ Just arg_and_res -> returnM arg_and_res
+ Nothing -> unify_fun_ty_help ty
+
+unify_fun_ty_help ty -- Special cases failed, so revert to ordinary unification
+ = newTyVarTy argTypeKind `thenM` \ arg ->
+ newTyVarTy openTypeKind `thenM` \ res ->
+ unifyTauTy ty (mkFunTy arg res) `thenM_`
+ returnM (arg,res)
+\end{code}
+
+\begin{code}
+----------------------
+zapToListTy, zapToPArrTy :: Expected TcType -- expected list type
+ -> TcM TcType -- list element type
+unifyListTy, unifyPArrTy :: TcType -> TcM TcType
+zapToListTy = zapToXTy listTyCon
+unifyListTy = unifyXTy listTyCon
+zapToPArrTy = zapToXTy parrTyCon
+unifyPArrTy = unifyXTy parrTyCon
+
+----------------------
+zapToXTy :: TyCon -- T :: *->*
+ -> Expected TcType -- Expected type (T a)
+ -> TcM TcType -- Element type, a
+
+zapToXTy tc (Check ty) = unifyXTy tc ty
+zapToXTy tc (Infer hole) = do { elt_ty <- newTyVarTy liftedTypeKind ;
+ writeMutVar hole (mkTyConApp tc [elt_ty]) ;
+ return elt_ty }
+
+----------------------
+unifyXTy :: TyCon -> TcType -> TcM TcType
+unifyXTy tc ty@(TyVarTy tyvar)
+ = getTcTyVar tyvar `thenM` \ maybe_ty ->
+ case maybe_ty of
+ Just ty' -> unifyXTy tc ty'
+ other -> unify_x_ty_help tc ty
+
+unifyXTy tc ty
+ = case tcSplitTyConApp_maybe ty of
+ Just (tycon, [arg_ty]) | tycon == tc -> returnM arg_ty
+ other -> unify_x_ty_help tc ty
+
+unify_x_ty_help tc ty -- Revert to ordinary unification
+ = newTyVarTy liftedTypeKind `thenM` \ elt_ty ->
+ unifyTauTy ty (mkTyConApp tc [elt_ty]) `thenM_`
+ returnM elt_ty
+\end{code}
+
+\begin{code}
+----------------------
+zapToTupleTy :: Boxity -> Arity -> Expected TcType -> TcM [TcType]
+zapToTupleTy boxity arity (Check ty) = unifyTupleTy boxity arity ty
+zapToTupleTy boxity arity (Infer hole) = do { (tup_ty, arg_tys) <- new_tuple_ty boxity arity ;
+ writeMutVar hole tup_ty ;
+ return arg_tys }
+
+unifyTupleTy boxity arity ty@(TyVarTy tyvar)
+ = getTcTyVar tyvar `thenM` \ maybe_ty ->
+ case maybe_ty of
+ Just ty' -> unifyTupleTy boxity arity ty'
+ other -> unify_tuple_ty_help boxity arity ty
+
+unifyTupleTy boxity arity ty
+ = case tcSplitTyConApp_maybe ty of
+ Just (tycon, arg_tys)
+ | isTupleTyCon tycon
+ && tyConArity tycon == arity
+ && tupleTyConBoxity tycon == boxity
+ -> returnM arg_tys
+ other -> unify_tuple_ty_help boxity arity ty
+
+unify_tuple_ty_help boxity arity ty
+ = new_tuple_ty boxity arity `thenM` \ (tup_ty, arg_tys) ->
+ unifyTauTy ty tup_ty `thenM_`
+ returnM arg_tys
+
+new_tuple_ty boxity arity
+ = newTyVarTys arity kind `thenM` \ arg_tys ->
+ return (mkTyConApp tup_tc arg_tys, arg_tys)
+ where
+ tup_tc = tupleTyCon boxity arity
+ kind | isBoxed boxity = liftedTypeKind
+ | otherwise = argTypeKind -- Components of an unboxed tuple
+ -- can be unboxed, but not unboxed tuples
\end{code}
%************************************************************************
%* *
+\subsection{Subsumption}
+%* *
+%************************************************************************
+
+All the tcSub calls have the form
+
+ tcSub expected_ty offered_ty
+which checks
+ offered_ty <= expected_ty
+
+That is, that a value of type offered_ty is acceptable in
+a place expecting a value of type expected_ty.
+
+It returns a coercion function
+ co_fn :: offered_ty -> expected_ty
+which takes an HsExpr of type offered_ty into one of type
+expected_ty.
+
+\begin{code}
+tcSubExp :: Expected TcRhoType -> TcRhoType -> TcM ExprCoFn
+tcSubOff :: TcSigmaType -> Expected TcSigmaType -> TcM ExprCoFn
+\end{code}
+
+These two check for holes
+
+\begin{code}
+tcSubExp expected_ty offered_ty
+ = traceTc (text "tcSubExp" <+> (ppr expected_ty $$ ppr offered_ty)) `thenM_`
+ checkHole expected_ty offered_ty tcSub
+
+tcSubOff expected_ty offered_ty
+ = checkHole offered_ty expected_ty (\ off exp -> tcSub exp off)
+
+-- checkHole looks for a hole in its first arg;
+-- If so, and it is uninstantiated, it fills in the hole
+-- with its second arg
+-- Otherwise it calls thing_inside, passing the two args, looking
+-- through any instantiated hole
+
+checkHole (Infer hole) other_ty thing_inside
+ = do { writeMutVar hole other_ty; return idCoercion }
+
+checkHole (Check ty) other_ty thing_inside
+ = thing_inside ty other_ty
+\end{code}
+
+No holes expected now. Add some error-check context info.
+
+\begin{code}
+tcSub :: TcSigmaType -> TcSigmaType -> TcM ExprCoFn -- Locally used only
+tcSub expected_ty actual_ty
+ = traceTc (text "tcSub" <+> details) `thenM_`
+ addErrCtxtM (unifyCtxt "type" expected_ty actual_ty)
+ (tc_sub expected_ty expected_ty actual_ty actual_ty)
+ where
+ details = vcat [text "Expected:" <+> ppr expected_ty,
+ text "Actual: " <+> ppr actual_ty]
+\end{code}
+
+tc_sub carries the types before and after expanding type synonyms
+
+\begin{code}
+tc_sub :: TcSigmaType -- expected_ty, before expanding synonyms
+ -> TcSigmaType -- ..and after
+ -> TcSigmaType -- actual_ty, before
+ -> TcSigmaType -- ..and after
+ -> TcM ExprCoFn
+
+-----------------------------------
+-- Expand synonyms
+tc_sub exp_sty (NoteTy _ exp_ty) act_sty act_ty = tc_sub exp_sty exp_ty act_sty act_ty
+tc_sub exp_sty exp_ty act_sty (NoteTy _ act_ty) = tc_sub exp_sty exp_ty act_sty act_ty
+
+-----------------------------------
+-- Generalisation case
+-- actual_ty: d:Eq b => b->b
+-- expected_ty: forall a. Ord a => a->a
+-- co_fn e /\a. \d2:Ord a. let d = eqFromOrd d2 in e
+
+-- It is essential to do this *before* the specialisation case
+-- Example: f :: (Eq a => a->a) -> ...
+-- g :: Ord b => b->b
+-- Consider f g !
+
+tc_sub exp_sty expected_ty act_sty actual_ty
+ | isSigmaTy expected_ty
+ = tcGen expected_ty (tyVarsOfType actual_ty) (
+ -- It's really important to check for escape wrt the free vars of
+ -- both expected_ty *and* actual_ty
+ \ body_exp_ty -> tc_sub body_exp_ty body_exp_ty act_sty actual_ty
+ ) `thenM` \ (gen_fn, co_fn) ->
+ returnM (gen_fn <.> co_fn)
+
+-----------------------------------
+-- Specialisation case:
+-- actual_ty: forall a. Ord a => a->a
+-- expected_ty: Int -> Int
+-- co_fn e = e Int dOrdInt
+
+tc_sub exp_sty expected_ty act_sty actual_ty
+ | isSigmaTy actual_ty
+ = tcInstCall Rank2Origin actual_ty `thenM` \ (inst_fn, body_ty) ->
+ tc_sub exp_sty expected_ty body_ty body_ty `thenM` \ co_fn ->
+ returnM (co_fn <.> inst_fn)
+
+-----------------------------------
+-- Function case
+
+tc_sub _ (FunTy exp_arg exp_res) _ (FunTy act_arg act_res)
+ = tcSub_fun exp_arg exp_res act_arg act_res
+
+-----------------------------------
+-- Type variable meets function: imitate
+--
+-- NB 1: we can't just unify the type variable with the type
+-- because the type might not be a tau-type, and we aren't
+-- allowed to instantiate an ordinary type variable with
+-- a sigma-type
+--
+-- NB 2: can we short-cut to an error case?
+-- when the arg/res is not a tau-type?
+-- NO! e.g. f :: ((forall a. a->a) -> Int) -> Int
+-- then x = (f,f)
+-- is perfectly fine, because we can instantiat f's type to a monotype
+--
+-- However, we get can get jolly unhelpful error messages.
+-- e.g. foo = id runST
+--
+-- Inferred type is less polymorphic than expected
+-- Quantified type variable `s' escapes
+-- Expected type: ST s a -> t
+-- Inferred type: (forall s1. ST s1 a) -> a
+-- In the first argument of `id', namely `runST'
+-- In a right-hand side of function `foo': id runST
+--
+-- I'm not quite sure what to do about this!
+
+tc_sub exp_sty exp_ty@(FunTy exp_arg exp_res) _ (TyVarTy tv)
+ = getTcTyVar tv `thenM` \ maybe_ty ->
+ case maybe_ty of
+ Just ty -> tc_sub exp_sty exp_ty ty ty
+ Nothing -> imitateFun tv exp_sty `thenM` \ (act_arg, act_res) ->
+ tcSub_fun exp_arg exp_res act_arg act_res
+
+tc_sub _ (TyVarTy tv) act_sty act_ty@(FunTy act_arg act_res)
+ = getTcTyVar tv `thenM` \ maybe_ty ->
+ case maybe_ty of
+ Just ty -> tc_sub ty ty act_sty act_ty
+ Nothing -> imitateFun tv act_sty `thenM` \ (exp_arg, exp_res) ->
+ tcSub_fun exp_arg exp_res act_arg act_res
+
+-----------------------------------
+-- Unification case
+-- If none of the above match, we revert to the plain unifier
+tc_sub exp_sty expected_ty act_sty actual_ty
+ = uTys exp_sty expected_ty act_sty actual_ty `thenM_`
+ returnM idCoercion
+\end{code}
+
+%************************************************************************
+%* *
+\subsection{Functions}
+%* *
+%************************************************************************
+
+\begin{code}
+tcSub_fun exp_arg exp_res act_arg act_res
+ = tc_sub act_arg act_arg exp_arg exp_arg `thenM` \ co_fn_arg ->
+ tc_sub exp_res exp_res act_res act_res `thenM` \ co_fn_res ->
+ newUnique `thenM` \ uniq ->
+ let
+ -- co_fn_arg :: HsExpr exp_arg -> HsExpr act_arg
+ -- co_fn_res :: HsExpr act_res -> HsExpr exp_res
+ -- co_fn :: HsExpr (act_arg -> act_res) -> HsExpr (exp_arg -> exp_res)
+ arg_id = mkSysLocal FSLIT("sub") uniq exp_arg
+ coercion | isIdCoercion co_fn_arg,
+ isIdCoercion co_fn_res = idCoercion
+ | otherwise = mkCoercion co_fn
+
+ co_fn e = DictLam [arg_id]
+ (noLoc (co_fn_res <$> (HsApp (noLoc e) (noLoc (co_fn_arg <$> HsVar arg_id)))))
+ -- Slight hack; using a "DictLam" to get an ordinary simple lambda
+ -- HsVar arg_id :: HsExpr exp_arg
+ -- co_fn_arg $it :: HsExpr act_arg
+ -- HsApp e $it :: HsExpr act_res
+ -- co_fn_res $it :: HsExpr exp_res
+ in
+ returnM coercion
+
+imitateFun :: TcTyVar -> TcType -> TcM (TcType, TcType)
+imitateFun tv ty
+ = -- NB: tv is an *ordinary* tyvar and so are the new ones
+
+ -- Check that tv isn't a type-signature type variable
+ -- (This would be found later in checkSigTyVars, but
+ -- we get a better error message if we do it here.)
+ checkM (not (isSkolemTyVar tv))
+ (failWithTcM (unifyWithSigErr tv ty)) `thenM_`
+
+ newTyVarTy argTypeKind `thenM` \ arg ->
+ newTyVarTy openTypeKind `thenM` \ res ->
+ putTcTyVar tv (mkFunTy arg res) `thenM_`
+ returnM (arg,res)
+\end{code}
+
+
+%************************************************************************
+%* *
+\subsection{Generalisation}
+%* *
+%************************************************************************
+
+\begin{code}
+tcGen :: TcSigmaType -- expected_ty
+ -> TcTyVarSet -- Extra tyvars that the universally
+ -- quantified tyvars of expected_ty
+ -- must not be unified
+ -> (TcRhoType -> TcM result) -- spec_ty
+ -> TcM (ExprCoFn, result)
+ -- The expression has type: spec_ty -> expected_ty
+
+tcGen expected_ty extra_tvs thing_inside -- We expect expected_ty to be a forall-type
+ -- If not, the call is a no-op
+ = tcInstType SigTv expected_ty `thenM` \ (forall_tvs, theta, phi_ty) ->
+
+ -- Type-check the arg and unify with poly type
+ getLIE (thing_inside phi_ty) `thenM` \ (result, lie) ->
+
+ -- Check that the "forall_tvs" havn't been constrained
+ -- The interesting bit here is that we must include the free variables
+ -- of the expected_ty. Here's an example:
+ -- runST (newVar True)
+ -- Here, if we don't make a check, we'll get a type (ST s (MutVar s Bool))
+ -- for (newVar True), with s fresh. Then we unify with the runST's arg type
+ -- forall s'. ST s' a. That unifies s' with s, and a with MutVar s Bool.
+ -- So now s' isn't unconstrained because it's linked to a.
+ -- Conclusion: include the free vars of the expected_ty in the
+ -- list of "free vars" for the signature check.
+
+ newDicts SignatureOrigin theta `thenM` \ dicts ->
+ tcSimplifyCheck sig_msg forall_tvs dicts lie `thenM` \ inst_binds ->
+
+#ifdef DEBUG
+ zonkTcTyVars forall_tvs `thenM` \ forall_tys ->
+ traceTc (text "tcGen" <+> vcat [text "extra_tvs" <+> ppr extra_tvs,
+ text "expected_ty" <+> ppr expected_ty,
+ text "inst ty" <+> ppr forall_tvs <+> ppr theta <+> ppr phi_ty,
+ text "free_tvs" <+> ppr free_tvs,
+ text "forall_tys" <+> ppr forall_tys]) `thenM_`
+#endif
+
+ checkSigTyVarsWrt free_tvs forall_tvs `thenM` \ zonked_tvs ->
+
+ traceTc (text "tcGen:done") `thenM_`
+
+ let
+ -- This HsLet binds any Insts which came out of the simplification.
+ -- It's a bit out of place here, but using AbsBind involves inventing
+ -- a couple of new names which seems worse.
+ dict_ids = map instToId dicts
+ co_fn e = TyLam zonked_tvs (mkHsDictLam dict_ids (mkHsLet inst_binds (noLoc e)))
+ in
+ returnM (mkCoercion co_fn, result)
+ where
+ free_tvs = tyVarsOfType expected_ty `unionVarSet` extra_tvs
+ sig_msg = ptext SLIT("expected type of an expression")
+\end{code}
+
+
+
+%************************************************************************
+%* *
\subsection[Unify-exported]{Exported unification functions}
%* *
%************************************************************************
Unify two @TauType@s. Dead straightforward.
\begin{code}
-unifyTauTy :: TcTauType -> TcTauType -> TcM s ()
+unifyTauTy :: TcTauType -> TcTauType -> TcM ()
unifyTauTy ty1 ty2 -- ty1 expected, ty2 inferred
- = tcAddErrCtxtM (unifyCtxt "type" ty1 ty2) $
+ = -- The unifier should only ever see tau-types
+ -- (no quantification whatsoever)
+ ASSERT2( isTauTy ty1, ppr ty1 )
+ ASSERT2( isTauTy ty2, ppr ty2 )
+ addErrCtxtM (unifyCtxt "type" ty1 ty2) $
uTys ty1 ty1 ty2 ty2
\end{code}
complain if their lengths differ.
\begin{code}
-unifyTauTyLists :: [TcTauType] -> [TcTauType] -> TcM s ()
-unifyTauTyLists [] [] = returnTc ()
-unifyTauTyLists (ty1:tys1) (ty2:tys2) = uTys ty1 ty1 ty2 ty2 `thenTc_`
+unifyTauTyLists :: [TcTauType] -> [TcTauType] -> TcM ()
+unifyTauTyLists [] [] = returnM ()
+unifyTauTyLists (ty1:tys1) (ty2:tys2) = uTys ty1 ty1 ty2 ty2 `thenM_`
unifyTauTyLists tys1 tys2
unifyTauTyLists ty1s ty2s = panic "Unify.unifyTauTyLists: mismatched type lists!"
\end{code}
lists, when all the elts should be of the same type.
\begin{code}
-unifyTauTyList :: [TcTauType] -> TcM s ()
-unifyTauTyList [] = returnTc ()
-unifyTauTyList [ty] = returnTc ()
-unifyTauTyList (ty1:tys@(ty2:_)) = unifyTauTy ty1 ty2 `thenTc_`
+unifyTauTyList :: [TcTauType] -> TcM ()
+unifyTauTyList [] = returnM ()
+unifyTauTyList [ty] = returnM ()
+unifyTauTyList (ty1:tys@(ty2:_)) = unifyTauTy ty1 ty2 `thenM_`
unifyTauTyList tys
\end{code}
\begin{code}
uTys :: TcTauType -> TcTauType -- Error reporting ty1 and real ty1
+ -- ty1 is the *expected* type
+
-> TcTauType -> TcTauType -- Error reporting ty2 and real ty2
- -> TcM s ()
+ -- ty2 is the *actual* type
+ -> TcM ()
-- Always expand synonyms (see notes at end)
-uTys ps_ty1 (NoteTy _ ty1) ps_ty2 ty2 = uTys ps_ty1 ty1 ps_ty2 ty2
-uTys ps_ty1 ty1 ps_ty2 (NoteTy _ ty2) = uTys ps_ty1 ty1 ps_ty2 ty2
+ -- (this also throws away FTVs)
+uTys ps_ty1 (NoteTy n1 ty1) ps_ty2 ty2 = uTys ps_ty1 ty1 ps_ty2 ty2
+uTys ps_ty1 ty1 ps_ty2 (NoteTy n2 ty2) = uTys ps_ty1 ty1 ps_ty2 ty2
-- Variables; go for uVar
uTys ps_ty1 (TyVarTy tyvar1) ps_ty2 ty2 = uVar False tyvar1 ps_ty2 ty2
uTys ps_ty1 ty1 ps_ty2 (TyVarTy tyvar2) = uVar True tyvar2 ps_ty1 ty1
-- "True" means args swapped
+ -- Predicates
+uTys _ (PredTy (IParam n1 t1)) _ (PredTy (IParam n2 t2))
+ | n1 == n2 = uTys t1 t1 t2 t2
+uTys _ (PredTy (ClassP c1 tys1)) _ (PredTy (ClassP c2 tys2))
+ | c1 == c2 = unifyTauTyLists tys1 tys2
+
-- Functions; just check the two parts
uTys _ (FunTy fun1 arg1) _ (FunTy fun2 arg2)
- = uTys fun1 fun1 fun2 fun2 `thenTc_` uTys arg1 arg1 arg2 arg2
+ = uTys fun1 fun1 fun2 fun2 `thenM_` uTys arg1 arg1 arg2 arg2
+
+ -- NewType constructors must match
+uTys _ (NewTcApp tc1 tys1) _ (NewTcApp tc2 tys2)
+ | tc1 == tc2 = unifyTauTyLists tys1 tys2
- -- Type constructors must match
+ -- Ordinary type constructors must match
uTys ps_ty1 (TyConApp con1 tys1) ps_ty2 (TyConApp con2 tys2)
- = checkTcM (cons_match && length tys1 == length tys2)
- (unifyMisMatch ps_ty1 ps_ty2) `thenTc_`
- unifyTauTyLists tys1 tys2
- where
- -- The AnyBox wild card matches anything
- cons_match = con1 == con2
- || con1 == anyBoxCon
- || con2 == anyBoxCon
+ | con1 == con2 && equalLength tys1 tys2
+ = unifyTauTyLists tys1 tys2
-- Applications need a bit of care!
-- They can match FunTy and TyConApp, so use splitAppTy_maybe
-- NB: we've already dealt with type variables and Notes,
-- so if one type is an App the other one jolly well better be too
uTys ps_ty1 (AppTy s1 t1) ps_ty2 ty2
- = case splitAppTy_maybe ty2 of
- Just (s2,t2) -> uTys s1 s1 s2 s2 `thenTc_` uTys t1 t1 t2 t2
+ = case tcSplitAppTy_maybe ty2 of
+ Just (s2,t2) -> uTys s1 s1 s2 s2 `thenM_` uTys t1 t1 t2 t2
Nothing -> unifyMisMatch ps_ty1 ps_ty2
-- Now the same, but the other way round
-- Don't swap the types, because the error messages get worse
uTys ps_ty1 ty1 ps_ty2 (AppTy s2 t2)
- = case splitAppTy_maybe ty1 of
- Just (s1,t1) -> uTys s1 s1 s2 s2 `thenTc_` uTys t1 t1 t2 t2
+ = case tcSplitAppTy_maybe ty1 of
+ Just (s1,t1) -> uTys s1 s1 s2 s2 `thenM_` uTys t1 t1 t2 t2
Nothing -> unifyMisMatch ps_ty1 ps_ty2
-- Not expecting for-alls in unification
uTys ps_ty1 ty1 ps_ty2 ty2 = unifyMisMatch ps_ty1 ps_ty2
\end{code}
+
Notes on synonyms
~~~~~~~~~~~~~~~~~
If you are tempted to make a short cut on synonyms, as in this
pseudocode...
\begin{verbatim}
-uTys (SynTy con1 args1 ty1) (SynTy con2 args2 ty2)
- = if (con1 == con2) then
- -- Good news! Same synonym constructors, so we can shortcut
- -- by unifying their arguments and ignoring their expansions.
- unifyTauTypeLists args1 args2
- else
- -- Never mind. Just expand them and try again
- uTys ty1 ty2
+-- NO uTys (SynTy con1 args1 ty1) (SynTy con2 args2 ty2)
+-- NO = if (con1 == con2) then
+-- NO -- Good news! Same synonym constructors, so we can shortcut
+-- NO -- by unifying their arguments and ignoring their expansions.
+-- NO unifyTauTypeLists args1 args2
+-- NO else
+-- NO -- Never mind. Just expand them and try again
+-- NO uTys ty1 ty2
\end{verbatim}
then THINK AGAIN. Here is the whole story, as detected and reported
-- True => ty is the "expected" thing
-> TcTyVar
-> TcTauType -> TcTauType -- printing and real versions
- -> TcM s ()
+ -> TcM ()
uVar swapped tv1 ps_ty2 ty2
- = tcGetTyVar tv1 `thenNF_Tc` \ maybe_ty1 ->
+ = traceTc (text "uVar" <+> ppr swapped <+> ppr tv1 <+> (ppr ps_ty2 $$ ppr ty2)) `thenM_`
+ getTcTyVar tv1 `thenM` \ maybe_ty1 ->
case maybe_ty1 of
Just ty1 | swapped -> uTys ps_ty2 ty2 ty1 ty1 -- Swap back
| otherwise -> uTys ty1 ty1 ps_ty2 ty2 -- Same order
- other -> uUnboundVar swapped tv1 maybe_ty1 ps_ty2 ty2
+ other -> uUnboundVar swapped tv1 ps_ty2 ty2
- -- Expand synonyms
-uUnboundVar swapped tv1 maybe_ty1 ps_ty2 (NoteTy _ ty2)
- = uUnboundVar swapped tv1 maybe_ty1 ps_ty2 ty2
+ -- Expand synonyms; ignore FTVs
+uUnboundVar swapped tv1 ps_ty2 (NoteTy n2 ty2)
+ = uUnboundVar swapped tv1 ps_ty2 ty2
-- The both-type-variable case
-uUnboundVar swapped tv1 maybe_ty1 ps_ty2 ty2@(TyVarTy tv2)
+uUnboundVar swapped tv1 ps_ty2 ty2@(TyVarTy tv2)
-- Same type variable => no-op
| tv1 == tv2
- = returnTc ()
+ = returnM ()
-- Distinct type variables
- -- ASSERT maybe_ty1 /= Just
| otherwise
- = tcGetTyVar tv2 `thenNF_Tc` \ maybe_ty2 ->
+ = getTcTyVar tv2 `thenM` \ maybe_ty2 ->
case maybe_ty2 of
- Just ty2' -> uUnboundVar swapped tv1 maybe_ty1 ty2' ty2'
+ Just ty2' -> uUnboundVar swapped tv1 ty2' ty2'
+
+ Nothing | update_tv2
+ -- It should always be the case that either k1 <: k2 or k2 <: k1
+ -- Reason: a type variable never gets the kinds (#) or #
- Nothing -> checkKinds swapped tv1 ty2 `thenTc_`
+ -> ASSERT2( k1 `isSubKind` k2, (ppr tv1 <+> ppr k1) $$ (ppr tv2 <+> ppr k2) )
+ putTcTyVar tv2 (TyVarTy tv1) `thenM_`
+ returnM ()
- -- Try to update sys-y type variables in preference to sig-y ones
- -- (the latter respond False to isSystemName)
- if isSystemName (varName tv2) then
- tcPutTyVar tv2 (TyVarTy tv1) `thenNF_Tc_`
- returnTc ()
- else
- tcPutTyVar tv1 ps_ty2 `thenNF_Tc_`
- returnTc ()
+ | otherwise
+ -> ASSERT2( k2 `isSubKind` k1, (ppr tv2 <+> ppr k2) $$ (ppr tv1 <+> ppr k1) )
+ putTcTyVar tv1 ps_ty2 `thenM_`
+ returnM ()
+ where
+ k1 = tyVarKind tv1
+ k2 = tyVarKind tv2
+ update_tv2 = k1 `isSubKind` k2 && (k1 /= k2 || nicer_to_update_tv2)
+ -- Update the variable with least kind info
+ -- See notes on type inference in Kind.lhs
+ -- The "nicer to" part only applies if the two kinds are the same,
+ -- so we can choose which to do.
+
+ nicer_to_update_tv2 = isUserTyVar tv1
+ -- Don't unify a signature type variable if poss
+ || isSystemName (varName tv2)
+ -- Try to update sys-y type variables in preference to sig-y ones
-- Second one isn't a type variable
-uUnboundVar swapped tv1 maybe_ty1 ps_ty2 non_var_ty2
- | non_var_ty2 == anyBoxKind
- -- If the
- = returnTc ()
+uUnboundVar swapped tv1 ps_ty2 non_var_ty2
+ = -- Check that tv1 isn't a type-signature type variable
+ checkM (not (isSkolemTyVar tv1))
+ (failWithTcM (unifyWithSigErr tv1 ps_ty2)) `thenM_`
+
+ -- Do the occurs check, and check that we are not
+ -- unifying a type variable with a polytype
+ -- Returns a zonked type ready for the update
+ checkValue tv1 ps_ty2 non_var_ty2 `thenM` \ ty2 ->
+
+ -- Check that the kinds match
+ checkKinds swapped tv1 ty2 `thenM_`
+
+ -- Perform the update
+ putTcTyVar tv1 ty2 `thenM_`
+ returnM ()
+\end{code}
- | otherwise
- = checkKinds swapped tv1 non_var_ty2 `thenTc_`
- occur_check non_var_ty2 `thenTc_`
- tcPutTyVar tv1 ps_ty2 `thenNF_Tc_`
- returnTc ()
- where
- occur_check ty = mapTc occur_check_tv (varSetElems (tyVarsOfType ty)) `thenTc_`
- returnTc ()
+\begin{code}
+checkKinds swapped tv1 ty2
+-- We're about to unify a type variable tv1 with a non-tyvar-type ty2.
+-- ty2 has been zonked at this stage, which ensures that
+-- its kind has as much boxity information visible as possible.
+ | tk2 `isSubKind` tk1 = returnM ()
- occur_check_tv tv2
- | tv1 == tv2 -- Same tyvar; fail
- = zonkTcType ps_ty2 `thenNF_Tc` \ zonked_ty2 ->
- failWithTcM (unifyOccurCheck tv1 zonked_ty2)
+ | otherwise
+ -- Either the kinds aren't compatible
+ -- (can happen if we unify (a b) with (c d))
+ -- or we are unifying a lifted type variable with an
+ -- unlifted type: e.g. (id 3#) is illegal
+ = addErrCtxtM (unifyKindCtxt swapped tv1 ty2) $
+ unifyKindMisMatch k1 k2
- | otherwise -- A different tyvar
- = tcGetTyVar tv2 `thenNF_Tc` \ maybe_ty2 ->
- case maybe_ty2 of
- Just ty2' -> occur_check ty2'
- other -> returnTc ()
+ where
+ (k1,k2) | swapped = (tk2,tk1)
+ | otherwise = (tk1,tk2)
+ tk1 = tyVarKind tv1
+ tk2 = typeKind ty2
+\end{code}
-checkKinds swapped tv1 ty2
- = tcAddErrCtxtM (unifyKindCtxt swapped tv1 ty2) $
-
- -- We have to use tcTypeKind not just typeKind to get the
- -- kind of ty2, because there might be mutable kind variables
- -- in the way. For example, suppose that ty2 :: (a b), and
- -- the kind of 'a' is a kind variable 'k' that has (presumably)
- -- been unified with 'k1 -> k2'.
- tcTypeKind ty2 `thenNF_Tc` \ k2 ->
-
- if swapped then
- unifyKind k2 (tyVarKind tv1)
- else
- unifyKind (tyVarKind tv1) k2
+\begin{code}
+checkValue tv1 ps_ty2 non_var_ty2
+-- Do the occurs check, and check that we are not
+-- unifying a type variable with a polytype
+-- Return the type to update the type variable with, or fail
+
+-- Basically we want to update tv1 := ps_ty2
+-- because ps_ty2 has type-synonym info, which improves later error messages
+--
+-- But consider
+-- type A a = ()
+--
+-- f :: (A a -> a -> ()) -> ()
+-- f = \ _ -> ()
+--
+-- x :: ()
+-- x = f (\ x p -> p x)
+--
+-- In the application (p x), we try to match "t" with "A t". If we go
+-- ahead and bind t to A t (= ps_ty2), we'll lead the type checker into
+-- an infinite loop later.
+-- But we should not reject the program, because A t = ().
+-- Rather, we should bind t to () (= non_var_ty2).
+--
+-- That's why we have this two-state occurs-check
+ = zonkTcType ps_ty2 `thenM` \ ps_ty2' ->
+ case okToUnifyWith tv1 ps_ty2' of {
+ Nothing -> returnM ps_ty2' ; -- Success
+ other ->
+
+ zonkTcType non_var_ty2 `thenM` \ non_var_ty2' ->
+ case okToUnifyWith tv1 non_var_ty2' of
+ Nothing -> -- This branch rarely succeeds, except in strange cases
+ -- like that in the example above
+ returnM non_var_ty2'
+
+ Just problem -> failWithTcM (unifyCheck problem tv1 ps_ty2')
+ }
+
+data Problem = OccurCheck | NotMonoType
+
+okToUnifyWith :: TcTyVar -> TcType -> Maybe Problem
+-- (okToUnifyWith tv ty) checks whether it's ok to unify
+-- tv :=: ty
+-- Nothing => ok
+-- Just p => not ok, problem p
+
+okToUnifyWith tv ty
+ = ok ty
+ where
+ ok (TyVarTy tv') | tv == tv' = Just OccurCheck
+ | otherwise = Nothing
+ ok (AppTy t1 t2) = ok t1 `and` ok t2
+ ok (FunTy t1 t2) = ok t1 `and` ok t2
+ ok (TyConApp _ ts) = oks ts
+ ok (NewTcApp _ ts) = oks ts
+ ok (ForAllTy _ _) = Just NotMonoType
+ ok (PredTy st) = ok_st st
+ ok (NoteTy (FTVNote _) t) = ok t
+ ok (NoteTy (SynNote t1) t2) = ok t1 `and` ok t2
+ -- Type variables may be free in t1 but not t2
+ -- A forall may be in t2 but not t1
+
+ oks ts = foldr (and . ok) Nothing ts
+
+ ok_st (ClassP _ ts) = oks ts
+ ok_st (IParam _ t) = ok t
+
+ Nothing `and` m = m
+ Just p `and` m = Just p
\end{code}
+
%************************************************************************
%* *
-\subsection[Unify-fun]{@unifyFunTy@}
+ Kind unification
%* *
%************************************************************************
-@unifyFunTy@ is used to avoid the fruitless creation of type variables.
-
-\begin{code}
-unifyFunTy :: TcType -- Fail if ty isn't a function type
- -> TcM s (TcType, TcType) -- otherwise return arg and result types
-
-unifyFunTy ty@(TyVarTy tyvar)
- = tcGetTyVar tyvar `thenNF_Tc` \ maybe_ty ->
- case maybe_ty of
- Just ty' -> unifyFunTy ty'
- other -> unify_fun_ty_help ty
-
-unifyFunTy ty
- = case splitFunTy_maybe ty of
- Just arg_and_res -> returnTc arg_and_res
- Nothing -> unify_fun_ty_help ty
-
-unify_fun_ty_help ty -- Special cases failed, so revert to ordinary unification
- = newTyVarTy_OpenKind `thenNF_Tc` \ arg ->
- newTyVarTy_OpenKind `thenNF_Tc` \ res ->
- unifyTauTy ty (mkFunTy arg res) `thenTc_`
- returnTc (arg,res)
-\end{code}
+Unifying kinds is much, much simpler than unifying types.
\begin{code}
-unifyListTy :: TcType -- expected list type
- -> TcM s TcType -- list element type
-
-unifyListTy ty@(TyVarTy tyvar)
- = tcGetTyVar tyvar `thenNF_Tc` \ maybe_ty ->
- case maybe_ty of
- Just ty' -> unifyListTy ty'
- other -> unify_list_ty_help ty
-
-unifyListTy ty
- = case splitTyConApp_maybe ty of
- Just (tycon, [arg_ty]) | tycon == listTyCon -> returnTc arg_ty
- other -> unify_list_ty_help ty
-
-unify_list_ty_help ty -- Revert to ordinary unification
- = newTyVarTy boxedTypeKind `thenNF_Tc` \ elt_ty ->
- unifyTauTy ty (mkListTy elt_ty) `thenTc_`
- returnTc elt_ty
-\end{code}
-
-\begin{code}
-unifyTupleTy :: Arity -> TcType -> TcM s [TcType]
-unifyTupleTy arity ty@(TyVarTy tyvar)
- = tcGetTyVar tyvar `thenNF_Tc` \ maybe_ty ->
- case maybe_ty of
- Just ty' -> unifyTupleTy arity ty'
- other -> unify_tuple_ty_help arity ty
-
-unifyTupleTy arity ty
- = case splitTyConApp_maybe ty of
- Just (tycon, arg_tys) | isTupleTyCon tycon
- && tyConArity tycon == arity
- -> returnTc arg_tys
- other -> unify_tuple_ty_help arity ty
-
-unify_tuple_ty_help arity ty
- = mapNF_Tc (\ _ -> newTyVarTy boxedTypeKind) [1..arity] `thenNF_Tc` \ arg_tys ->
- unifyTauTy ty (mkTupleTy arity arg_tys) `thenTc_`
- returnTc arg_tys
+unifyKind :: TcKind -- Expected
+ -> TcKind -- Actual
+ -> TcM ()
+unifyKind LiftedTypeKind LiftedTypeKind = returnM ()
+unifyKind UnliftedTypeKind UnliftedTypeKind = returnM ()
+
+unifyKind OpenTypeKind k2 | isOpenTypeKind k2 = returnM ()
+unifyKind ArgTypeKind k2 | isArgTypeKind k2 = returnM ()
+ -- Respect sub-kinding
+
+unifyKind (FunKind a1 r1) (FunKind a2 r2)
+ = do { unifyKind a2 a1; unifyKind r1 r2 }
+ -- Notice the flip in the argument,
+ -- so that the sub-kinding works right
+
+unifyKind (KindVar kv1) k2 = uKVar False kv1 k2
+unifyKind k1 (KindVar kv2) = uKVar True kv2 k1
+unifyKind k1 k2 = unifyKindMisMatch k1 k2
+
+unifyKinds :: [TcKind] -> [TcKind] -> TcM ()
+unifyKinds [] [] = returnM ()
+unifyKinds (k1:ks1) (k2:ks2) = unifyKind k1 k2 `thenM_`
+ unifyKinds ks1 ks2
+unifyKinds _ _ = panic "unifyKinds: length mis-match"
+
+----------------
+uKVar :: Bool -> KindVar -> TcKind -> TcM ()
+uKVar swapped kv1 k2
+ = do { mb_k1 <- readKindVar kv1
+ ; case mb_k1 of
+ Nothing -> uUnboundKVar swapped kv1 k2
+ Just k1 | swapped -> unifyKind k2 k1
+ | otherwise -> unifyKind k1 k2 }
+
+----------------
+uUnboundKVar :: Bool -> KindVar -> TcKind -> TcM ()
+uUnboundKVar swapped kv1 k2@(KindVar kv2)
+ | kv1 == kv2 = returnM ()
+ | otherwise -- Distinct kind variables
+ = do { mb_k2 <- readKindVar kv2
+ ; case mb_k2 of
+ Just k2 -> uUnboundKVar swapped kv1 k2
+ Nothing -> writeKindVar kv1 k2 }
+
+uUnboundKVar swapped kv1 non_var_k2
+ = do { k2' <- zonkTcKind non_var_k2
+ ; kindOccurCheck kv1 k2'
+ ; k2'' <- kindSimpleKind swapped k2'
+ -- KindVars must be bound only to simple kinds
+ -- Polarities: (kindSimpleKind True ?) succeeds
+ -- returning *, corresponding to unifying
+ -- expected: ?
+ -- actual: kind-ver
+ ; writeKindVar kv1 k2'' }
+
+----------------
+kindOccurCheck kv1 k2 -- k2 is zonked
+ = checkTc (not_in k2) (kindOccurCheckErr kv1 k2)
+ where
+ not_in (KindVar kv2) = kv1 /= kv2
+ not_in (FunKind a2 r2) = not_in a2 && not_in r2
+ not_in other = True
+
+kindSimpleKind :: Bool -> Kind -> TcM SimpleKind
+-- (kindSimpleKind True k) returns a simple kind sk such that sk <: k
+-- If the flag is False, it requires k <: sk
+-- E.g. kindSimpleKind False ?? = *
+-- What about (kv -> *) :=: ?? -> *
+kindSimpleKind orig_swapped orig_kind
+ = go orig_swapped orig_kind
+ where
+ go sw (FunKind k1 k2) = do { k1' <- go (not sw) k1
+ ; k2' <- go sw k2
+ ; return (FunKind k1' k2') }
+ go True OpenTypeKind = return liftedTypeKind
+ go True ArgTypeKind = return liftedTypeKind
+ go sw LiftedTypeKind = return liftedTypeKind
+ go sw k@(KindVar _) = return k -- KindVars are always simple
+ go swapped kind = failWithTc (ptext SLIT("Unexpected kind unification failure:")
+ <+> ppr orig_swapped <+> ppr orig_kind)
+ -- I think this can't actually happen
+
+-- T v = MkT v v must be a type
+-- T v w = MkT (v -> w) v must not be an umboxed tuple
+
+----------------
+kindOccurCheckErr tyvar ty
+ = hang (ptext SLIT("Occurs check: cannot construct the infinite kind:"))
+ 2 (sep [ppr tyvar, char '=', ppr ty])
+
+unifyKindMisMatch ty1 ty2
+ = zonkTcKind ty1 `thenM` \ ty1' ->
+ zonkTcKind ty2 `thenM` \ ty2' ->
+ let
+ msg = hang (ptext SLIT("Couldn't match kind"))
+ 2 (sep [quotes (ppr ty1'),
+ ptext SLIT("against"),
+ quotes (ppr ty2')])
+ in
+ failWithTc msg
\end{code}
\begin{code}
-unifyUnboxedTupleTy :: Arity -> TcType -> TcM s [TcType]
-unifyUnboxedTupleTy arity ty@(TyVarTy tyvar)
- = tcGetTyVar tyvar `thenNF_Tc` \ maybe_ty ->
- case maybe_ty of
- Just ty' -> unifyUnboxedTupleTy arity ty'
- other -> unify_unboxed_tuple_ty_help arity ty
-
-unifyUnboxedTupleTy arity ty
- = case splitTyConApp_maybe ty of
- Just (tycon, arg_tys) | isUnboxedTupleTyCon tycon
- && tyConArity tycon == arity
- -> returnTc arg_tys
- other -> unify_tuple_ty_help arity ty
-
-unify_unboxed_tuple_ty_help arity ty
- = mapNF_Tc (\ _ -> newTyVarTy_OpenKind) [1..arity] `thenNF_Tc` \ arg_tys ->
- unifyTauTy ty (mkUnboxedTupleTy arity arg_tys) `thenTc_`
- returnTc arg_tys
-\end{code}
+unifyFunKind :: TcKind -> TcM (Maybe (TcKind, TcKind))
+-- Like unifyFunTy, but does not fail; instead just returns Nothing
-Make sure a kind is of the form (Type b) for some boxity b.
-
-\begin{code}
-unifyTypeKind :: TcKind -> TcM s ()
-unifyTypeKind kind@(TyVarTy kv)
- = tcGetTyVar kv `thenNF_Tc` \ maybe_kind ->
+unifyFunKind (KindVar kvar)
+ = readKindVar kvar `thenM` \ maybe_kind ->
case maybe_kind of
- Just kind' -> unifyTypeKind kind'
- Nothing -> unify_type_kind_help kind
-
-unifyTypeKind kind
- = case splitTyConApp_maybe kind of
- Just (tycon, [_]) | tycon == typeCon -> returnTc ()
- other -> unify_type_kind_help kind
-
-unify_type_kind_help kind
- = newOpenTypeKind `thenNF_Tc` \ expected_kind ->
- unifyKind expected_kind kind
+ Just fun_kind -> unifyFunKind fun_kind
+ Nothing -> do { arg_kind <- newKindVar
+ ; res_kind <- newKindVar
+ ; writeKindVar kvar (mkArrowKind arg_kind res_kind)
+ ; returnM (Just (arg_kind,res_kind)) }
+
+unifyFunKind (FunKind arg_kind res_kind) = returnM (Just (arg_kind,res_kind))
+unifyFunKind other = returnM Nothing
\end{code}
-
%************************************************************************
%* *
\subsection[Unify-context]{Errors and contexts}
\begin{code}
unifyCtxt s ty1 ty2 tidy_env -- ty1 expected, ty2 inferred
- = zonkTcType ty1 `thenNF_Tc` \ ty1' ->
- zonkTcType ty2 `thenNF_Tc` \ ty2' ->
- returnNF_Tc (err ty1' ty2')
+ = zonkTcType ty1 `thenM` \ ty1' ->
+ zonkTcType ty2 `thenM` \ ty2' ->
+ returnM (err ty1' ty2')
where
err ty1 ty2 = (env1,
- nest 4
+ nest 2
(vcat [
text "Expected" <+> text s <> colon <+> ppr tidy_ty1,
text "Inferred" <+> text s <> colon <+> ppr tidy_ty2
(env1, [tidy_ty1,tidy_ty2]) = tidyOpenTypes tidy_env [ty1,ty2]
unifyKindCtxt swapped tv1 ty2 tidy_env -- not swapped => tv1 expected, ty2 inferred
- = returnNF_Tc (env2, ptext SLIT("When matching types") <+>
- sep [quotes pp_expected, ptext SLIT("and"), quotes pp_actual])
+ -- tv1 and ty2 are zonked already
+ = returnM msg
where
+ msg = (env2, ptext SLIT("When matching types") <+>
+ sep [quotes pp_expected <+> ptext SLIT("and"), quotes pp_actual])
+
(pp_expected, pp_actual) | swapped = (pp2, pp1)
- | otherwise = (pp1, pp2)
- (env1, tv1') = tidyTyVar tidy_env tv1
- (env2, ty2') = tidyOpenType env1 ty2
- pp1 = ppr tv1'
- pp2 = ppr ty2'
+ | otherwise = (pp1, pp2)
+ (env1, tv1') = tidyOpenTyVar tidy_env tv1
+ (env2, ty2') = tidyOpenType env1 ty2
+ pp1 = ppr tv1' <+> dcolon <+> ppr (tyVarKind tv1)
+ pp2 = ppr ty2' <+> dcolon <+> ppr (typeKind ty2)
unifyMisMatch ty1 ty2
- = zonkTcType ty1 `thenNF_Tc` \ ty1' ->
- zonkTcType ty2 `thenNF_Tc` \ ty2' ->
+ = zonkTcType ty1 `thenM` \ ty1' ->
+ zonkTcType ty2 `thenM` \ ty2' ->
let
(env, [tidy_ty1, tidy_ty2]) = tidyOpenTypes emptyTidyEnv [ty1',ty2']
msg = hang (ptext SLIT("Couldn't match"))
- 4 (sep [quotes (ppr tidy_ty1),
+ 2 (sep [quotes (ppr tidy_ty1),
ptext SLIT("against"),
quotes (ppr tidy_ty2)])
in
failWithTcM (env, msg)
-unifyOccurCheck tyvar ty
- = (env2, hang (ptext SLIT("Occurs check: cannot construct the infinite type:"))
- 4 (sep [ppr tidy_tyvar, char '=', ppr tidy_ty]))
+
+unifyWithSigErr tyvar ty
+ = (env2, hang (ptext SLIT("Cannot unify the type-signature variable") <+> quotes (ppr tidy_tyvar))
+ 2 (ptext SLIT("with the type") <+> quotes (ppr tidy_ty)))
+ where
+ (env1, tidy_tyvar) = tidyOpenTyVar emptyTidyEnv tyvar
+ (env2, tidy_ty) = tidyOpenType env1 ty
+
+unifyCheck problem tyvar ty
+ = (env2, hang msg
+ 2 (sep [ppr tidy_tyvar, char '=', ppr tidy_ty]))
where
- (env1, tidy_tyvar) = tidyTyVar emptyTidyEnv tyvar
- (env2, tidy_ty) = tidyOpenType env1 ty
+ (env1, tidy_tyvar) = tidyOpenTyVar emptyTidyEnv tyvar
+ (env2, tidy_ty) = tidyOpenType env1 ty
+
+ msg = case problem of
+ OccurCheck -> ptext SLIT("Occurs check: cannot construct the infinite type:")
+ NotMonoType -> ptext SLIT("Cannot unify a type variable with a type scheme:")
+\end{code}
+
+
+%************************************************************************
+%* *
+ Checking kinds
+%* *
+%************************************************************************
+
+---------------------------
+-- We would like to get a decent error message from
+-- (a) Under-applied type constructors
+-- f :: (Maybe, Maybe)
+-- (b) Over-applied type constructors
+-- f :: Int x -> Int x
+--
+
+\begin{code}
+checkExpectedKind :: Outputable a => a -> TcKind -> TcKind -> TcM ()
+-- A fancy wrapper for 'unifyKind', which tries
+-- to give decent error messages.
+checkExpectedKind ty act_kind exp_kind
+ | act_kind `isSubKind` exp_kind -- Short cut for a very common case
+ = returnM ()
+ | otherwise
+ = tryTc (unifyKind exp_kind act_kind) `thenM` \ (errs, mb_r) ->
+ case mb_r of {
+ Just _ -> returnM () ; -- Unification succeeded
+ Nothing ->
+
+ -- So there's definitely an error
+ -- Now to find out what sort
+ zonkTcKind exp_kind `thenM` \ exp_kind ->
+ zonkTcKind act_kind `thenM` \ act_kind ->
+
+ let (exp_as, _) = splitKindFunTys exp_kind
+ (act_as, _) = splitKindFunTys act_kind
+ n_exp_as = length exp_as
+ n_act_as = length act_as
+
+ err | n_exp_as < n_act_as -- E.g. [Maybe]
+ = quotes (ppr ty) <+> ptext SLIT("is not applied to enough type arguments")
+
+ -- Now n_exp_as >= n_act_as. In the next two cases,
+ -- n_exp_as == 0, and hence so is n_act_as
+ | isLiftedTypeKind exp_kind && isUnliftedTypeKind act_kind
+ = ptext SLIT("Expecting a lifted type, but") <+> quotes (ppr ty)
+ <+> ptext SLIT("is unlifted")
+
+ | isUnliftedTypeKind exp_kind && isLiftedTypeKind act_kind
+ = ptext SLIT("Expecting an unlifted type, but") <+> quotes (ppr ty)
+ <+> ptext SLIT("is lifted")
+
+ | otherwise -- E.g. Monad [Int]
+ = sep [ ptext SLIT("Expecting kind") <+> quotes (pprKind exp_kind) <> comma,
+ ptext SLIT("but") <+> quotes (ppr ty) <+>
+ ptext SLIT("has kind") <+> quotes (pprKind act_kind)]
+ in
+ failWithTc (ptext SLIT("Kind error:") <+> err)
+ }
+\end{code}
+
+%************************************************************************
+%* *
+\subsection{Checking signature type variables}
+%* *
+%************************************************************************
+
+@checkSigTyVars@ is used after the type in a type signature has been unified with
+the actual type found. It then checks that the type variables of the type signature
+are
+ (a) Still all type variables
+ eg matching signature [a] against inferred type [(p,q)]
+ [then a will be unified to a non-type variable]
+
+ (b) Still all distinct
+ eg matching signature [(a,b)] against inferred type [(p,p)]
+ [then a and b will be unified together]
+
+ (c) Not mentioned in the environment
+ eg the signature for f in this:
+
+ g x = ... where
+ f :: a->[a]
+ f y = [x,y]
+
+ Here, f is forced to be monorphic by the free occurence of x.
+
+ (d) Not (unified with another type variable that is) in scope.
+ eg f x :: (r->r) = (\y->y) :: forall a. a->r
+ when checking the expression type signature, we find that
+ even though there is nothing in scope whose type mentions r,
+ nevertheless the type signature for the expression isn't right.
+
+ Another example is in a class or instance declaration:
+ class C a where
+ op :: forall b. a -> b
+ op x = x
+ Here, b gets unified with a
+
+Before doing this, the substitution is applied to the signature type variable.
+
+We used to have the notion of a "DontBind" type variable, which would
+only be bound to itself or nothing. Then points (a) and (b) were
+self-checking. But it gave rise to bogus consequential error messages.
+For example:
+
+ f = (*) -- Monomorphic
+
+ g :: Num a => a -> a
+ g x = f x x
+
+Here, we get a complaint when checking the type signature for g,
+that g isn't polymorphic enough; but then we get another one when
+dealing with the (Num x) context arising from f's definition;
+we try to unify x with Int (to default it), but find that x has already
+been unified with the DontBind variable "a" from g's signature.
+This is really a problem with side-effecting unification; we'd like to
+undo g's effects when its type signature fails, but unification is done
+by side effect, so we can't (easily).
+
+So we revert to ordinary type variables for signatures, and try to
+give a helpful message in checkSigTyVars.
+
+\begin{code}
+checkSigTyVars :: [TcTyVar] -> TcM [TcTyVar]
+checkSigTyVars sig_tvs = check_sig_tyvars emptyVarSet sig_tvs
+
+checkSigTyVarsWrt :: TcTyVarSet -> [TcTyVar] -> TcM [TcTyVar]
+checkSigTyVarsWrt extra_tvs sig_tvs
+ = zonkTcTyVarsAndFV (varSetElems extra_tvs) `thenM` \ extra_tvs' ->
+ check_sig_tyvars extra_tvs' sig_tvs
+
+check_sig_tyvars
+ :: TcTyVarSet -- Global type variables. The universally quantified
+ -- tyvars should not mention any of these
+ -- Guaranteed already zonked.
+ -> [TcTyVar] -- Universally-quantified type variables in the signature
+ -- Not guaranteed zonked.
+ -> TcM [TcTyVar] -- Zonked signature type variables
+
+check_sig_tyvars extra_tvs []
+ = returnM []
+check_sig_tyvars extra_tvs sig_tvs
+ = zonkTcTyVars sig_tvs `thenM` \ sig_tys ->
+ tcGetGlobalTyVars `thenM` \ gbl_tvs ->
+ let
+ env_tvs = gbl_tvs `unionVarSet` extra_tvs
+ in
+ traceTc (text "check_sig_tyvars" <+> (vcat [text "sig_tys" <+> ppr sig_tys,
+ text "gbl_tvs" <+> ppr gbl_tvs,
+ text "extra_tvs" <+> ppr extra_tvs])) `thenM_`
+
+ checkM (allDistinctTyVars sig_tys env_tvs)
+ (complain sig_tys env_tvs) `thenM_`
+
+ returnM (map (tcGetTyVar "checkSigTyVars") sig_tys)
+
+ where
+ complain sig_tys globals
+ = -- "check" checks each sig tyvar in turn
+ foldlM check
+ (env2, emptyVarEnv, [])
+ (tidy_tvs `zip` tidy_tys) `thenM` \ (env3, _, msgs) ->
+
+ failWithTcM (env3, main_msg $$ nest 2 (vcat msgs))
+ where
+ (env1, tidy_tvs) = tidyOpenTyVars emptyTidyEnv sig_tvs
+ (env2, tidy_tys) = tidyOpenTypes env1 sig_tys
+
+ main_msg = ptext SLIT("Inferred type is less polymorphic than expected")
+
+ check (tidy_env, acc, msgs) (sig_tyvar,ty)
+ -- sig_tyvar is from the signature;
+ -- ty is what you get if you zonk sig_tyvar and then tidy it
+ --
+ -- acc maps a zonked type variable back to a signature type variable
+ = case tcGetTyVar_maybe ty of {
+ Nothing -> -- Error (a)!
+ returnM (tidy_env, acc, unify_msg sig_tyvar (quotes (ppr ty)) : msgs) ;
+
+ Just tv ->
+
+ case lookupVarEnv acc tv of {
+ Just sig_tyvar' -> -- Error (b)!
+ returnM (tidy_env, acc, unify_msg sig_tyvar thing : msgs)
+ where
+ thing = ptext SLIT("another quantified type variable") <+> quotes (ppr sig_tyvar')
+
+ ; Nothing ->
+
+ if tv `elemVarSet` globals -- Error (c) or (d)! Type variable escapes
+ -- The least comprehensible, so put it last
+ -- Game plan:
+ -- get the local TcIds and TyVars from the environment,
+ -- and pass them to find_globals (they might have tv free)
+ then findGlobals (unitVarSet tv) tidy_env `thenM` \ (tidy_env1, globs) ->
+ returnM (tidy_env1, acc, escape_msg sig_tyvar tv globs : msgs)
+
+ else -- All OK
+ returnM (tidy_env, extendVarEnv acc tv sig_tyvar, msgs)
+ }}
+\end{code}
+
+
+\begin{code}
+-----------------------
+escape_msg sig_tv tv globs
+ = mk_msg sig_tv <+> ptext SLIT("escapes") $$
+ if notNull globs then
+ vcat [pp_it <+> ptext SLIT("is mentioned in the environment:"),
+ nest 2 (vcat globs)]
+ else
+ empty -- Sigh. It's really hard to give a good error message
+ -- all the time. One bad case is an existential pattern match.
+ -- We rely on the "When..." context to help.
+ where
+ pp_it | sig_tv /= tv = ptext SLIT("It unifies with") <+> quotes (ppr tv) <> comma <+> ptext SLIT("which")
+ | otherwise = ptext SLIT("It")
+
+
+unify_msg tv thing = mk_msg tv <+> ptext SLIT("is unified with") <+> thing
+mk_msg tv = ptext SLIT("Quantified type variable") <+> quotes (ppr tv)
\end{code}
+These two context are used with checkSigTyVars
+
+\begin{code}
+sigCtxt :: Id -> [TcTyVar] -> TcThetaType -> TcTauType
+ -> TidyEnv -> TcM (TidyEnv, Message)
+sigCtxt id sig_tvs sig_theta sig_tau tidy_env
+ = zonkTcType sig_tau `thenM` \ actual_tau ->
+ let
+ (env1, tidy_sig_tvs) = tidyOpenTyVars tidy_env sig_tvs
+ (env2, tidy_sig_rho) = tidyOpenType env1 (mkPhiTy sig_theta sig_tau)
+ (env3, tidy_actual_tau) = tidyOpenType env2 actual_tau
+ sub_msg = vcat [ptext SLIT("Signature type: ") <+> pprType (mkForAllTys tidy_sig_tvs tidy_sig_rho),
+ ptext SLIT("Type to generalise:") <+> pprType tidy_actual_tau
+ ]
+ msg = vcat [ptext SLIT("When trying to generalise the type inferred for") <+> quotes (ppr id),
+ nest 2 sub_msg]
+ in
+ returnM (env3, msg)
+\end{code}